基于大气环境下全无机钙钛矿薄膜及碳基太阳能电池的组分调控和添加剂工程

仲婷婷; 郝会颖

doi:10.7498/aps.73.20241439

摘要

全无机CsPbX₃材料作为一种新型的钙钛矿材料, 应用于太阳能电池, 具有生产高效、稳定的商用器件的潜在前景, 但由空穴传输材料和贵金属电极所带来的成本和稳定性问题却亟需解决, 由此基于无空穴传输层结构(HTL-free)的全无机体系的碳基钙钛矿太阳能电池(C-PSCs)引起了广泛关注. 本文通过精细调控X位卤素阴离子中I和Br的比例, 基于一步反溶剂法, 在大气环境下制备CsPbI_xBr_3–x薄膜和HTL-free C-PSCs, 找到兼顾效率和稳定的平衡点. 之后, 为进一步提高相应器件的性能, 将苯乙基溴化胺(PEABr)引入钙钛矿中, 最终基于PEABr处理后的钙钛矿薄膜具有更好的结晶度以及更低的缺陷态密度, 而生成少量二维钙钛矿能够钝化钙钛矿薄膜, 并抑制载流子的非辐射复合. 通过适量PEABr处理后, 器件的光电转换效率(PCE)显著增强, 从对照组最佳器件的10.18%提高到12.61%. 由此, 该方法为大气环境下制备高效率、低成本的HTL-free C-PSCs提供了优化思路.

关键词:

Abstract

The new all-inorganic CsPbX₃ perovskite material is expected to be used as an absorbing layer to prepare solar cells for efficient and stable commercial devices. However, the problems of high cost and poor stability, caused by precious metal electrodes and hole transport materials, urgently need solving. Therefore, carbon-based perovskite solar cells (C-PSCs) based on the HTL-free all-inorganic system have attracted widespread attention. This work adopts a strategy of finely regulating the ratio of I to Br in X-site of perovskite. Using the one-step anti-solvent method, CsPbI_xBr_3–x films and HTL-free C-PSCs are prepared under ambient air condition. By comparing their light absorption characteristics, carrier transport, and corresponding optoelectronic properties, a balance point between efficiency and stability is found. Finally, HTL-free C-PSCs achieve an optimal efficiency of 10.10% and can be stably prepared under ambient air conditions. In order to further improve the performance of the corresponding devices, phenylethylammonium bromide (PEABr) is introduced into the perovskite, and the crystallinity, carrier transport, defect situation, and corresponding optoelectronic properties of perovskite films and devices are compared under different conditions. Ultimately, the perovskite film treated with PEABr reaches better crystallinity and lower defect density, while generating a small amount of two-dimensional perovskite which can passivate the perovskite film and suppress non-radiative recombination of charge carriers. After appropriate PEABr treatment, the photoelectric conversion efficiency (PCE) of the device is significantly enhanced, increasing from 10.18% of the optimal device in the control group to 12.61%. Thus, this method provides an optimal approach for preparing efficient and low-cost HTL-free C-PSCs under ambient air environments.

Keywords:

作者及机构信息

仲婷婷^1,2,
郝会颖³

1.
天津城建大学材料科学与工程学院, 天津　300384

2.
天津市建筑绿色功能材料重点实验室, 天津　300384

3.
中国地质大学(北京)数理学院, 北京　100083

通信作者: 郝会颖, huiyinghaoL@cugb.edu.cn

基金项目: 中国科学院半导体研究所半导体材料科学重点实验室开放基金(批准号: KLSMS-1901)资助的课题.

Authors and contacts

1.
School of Materials Science and Engineering, Tianjin Chengjian University, Tianjin 300384, China

2.
Tianjin Key Laboratory of Building Green Functional Materials, Tianjin 300384, China

3.
School of Science, China University of Geosciences (Beijing), Beijing 100083, China

Corresponding author: Hao Hui-Ying, huiyinghaoL@cugb.edu.cn

Funds: Project supported by the Open Foundation of Key Laboratory of Semiconductor Materials Science Institute of Semiconductors, Chinese Academy of Sciences (Grant No. KLSMS-1901).

文章全文 : translate this paragraph

参考文献

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施引文献

图 1 基于组分调控策略制备钙钛矿薄膜的流程示意图

Fig. 1. Schematic diagram of the process for preparing perovskite films based on component control strategy.

下载: 全尺寸图片幻灯片

图 2 基于添加剂工程制备钙钛矿薄膜的流程示意图

Fig. 2. Schematic diagram of the process for preparing perovskite films based on additive engineering.

下载: 全尺寸图片幻灯片

图 3 钙钛矿前驱液照片　(a) 过滤前; (b) 过滤后

Fig. 3. Photograph of perovskite precursor solution: (a) Before filtration; (b) after filtering.

下载: 全尺寸图片幻灯片

图 4 CsPbI_xBr_3–x薄膜照片　(a) 刚退火后; (b) 大气环境下放置一周后

Fig. 4. Photograph of CsPbI_xBr_3–x films: (a) Just after annealing; (b) after being placed in ambient air environment for one week.

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图 5 CsPbI_xBr_3–x薄膜的UV-vis光谱图

Fig. 5. UV-vis spectra of CsPbI_xBr_3–x films.

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图 6 CsPbI_xBr_3–x薄膜的稳态PL光谱图

Fig. 6. Steady state PL spectrum of CsPbI_xBr_3–x films.

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图 7 CsPbI_xBr_3–x不同I-Br配比下的最佳器件的J-V曲线

Fig. 7. J-V curves of optimal devices with different I-Br ratios for CsPbI_xBr_3–x.

下载: 全尺寸图片幻灯片

图 8 不同含量PEABr处理的钙钛矿薄膜的XRD图

Fig. 8. XRD patterns of perovskite films treated with different concentrations of PEABr.

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图 9 不同含量PEABr处理的钙钛矿薄膜的稳态PL光谱图

Fig. 9. Steady state PL spectrum of perovskite films treated with different concentrations of PEABr.

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图 10 不同含量PEABr处理的最佳器件的J-V曲线

Fig. 10. J-V curves of optimal devices treated with different concentrations of PEABr.

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图 11 不同含量PEABr处理的器件的光伏统计　(a) V_OC; (b) J_SC; (c) FF; (d) PCE

Fig. 11. Photovoltaic statistics of devices treated with different concentrations of PEABr: (a) V_OC; (b) J_SC; (c) FF; (d) PCE.

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图 12 有无PEABr处理的器件在最大功率点时的稳态光电流和输出PCE

Fig. 12. Steady state photocurrent and output PCE of devices with or without PEABr processing at maximum power point.

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图 13 有无PEABr处理的器件的暗态J-V曲线

Fig. 13. Dark state J-V curves of devices with or without PEABr treatment.

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图 14 有无PEABr处理的器件的SCLC曲线

Fig. 14. SCLC curves of devices with or without PEABr treatment.

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图 15 有无PEABr处理的器件的电化学阻抗谱(插图为等效电路图)

Fig. 15. Electrochemical impedance spectroscopy of devices with or without PEABr treatment (illustrated as equivalent circuit diagram).

下载: 全尺寸图片幻灯片

表 1 CsPbI_xBr_3–x不同I-Br配比下的最佳器件的具体光伏参数

Table 1. The specific photovoltaic parameters of CsPbI_xBr_3–x devices with different I-Br ratios.

Device	V_OC/V	J_SC/(mA·cm^–2)	FF/%	PCE/%
CsPbIBr₂	1.29	7.74	50.68	5.09
CsPbI_1.2Br_1.8	1.27	9.47	54.63	6.57
CsPbI_1.4Br_1.6	1.26	10.46	55.54	7.32
CsPbI_1.6Br_1.4	1.25	11.99	56.91	8.53
CsPbI_1.8Br_1.2	1.22	12.95	63.93	10.10
CsPbI₂Br	1.21	13.61	62.30	10.26

下载: 导出CSV

表 2 不同含量PEABr处理的器件的具体光伏参数

Table 2. Specific photovoltaic parameters of devices treated with PEABr at different concentrations.

Device	Type	V_OC/V	J_SC/(mA·cm^–2)	FF/%	PCE/%
w/o-PEABr	Max	1.23	13.18	62.59	10.18
w/o-PEABr	Average	1.22 ± 0.02	13.22 ± 0.22	60.08 ± 2.45	9.66 ± 0.41
30-PEABr	Max	1.26	14.15	65.92	11.73
30-PEABr	Average	1.25 ± 0.02	14.01 ± 0.68	62.55 ± 1.79	10.93 ± 0.49
50-PEABr	Max	1.28	15.19	64.98	12.61
50-PEABr	Average	1.28 ± 0.02	14.71 ± 0.62	63.14 ± 1.65	11.84 ± 0.54
70-PEABr	Max	1.27	14.92	63.72	12.05
70-PEABr	Average	1.27 ± 0.02	14.24 ± 0.45	61.96 ± 1.03	11.18 ± 0.49
注: 表中的平均值是由40组器件(每个条件10组)计算得出.

下载: 导出CSV

表 3 有无PEABr处理的器件的Nyquist plots模拟结果

Table 3. Nyquist plot simulation results of devices with and without PEABr processing.

Device	R_S/Ω	R_rec/Ω
w/o-PEABr	68.89	6776
with-PEABr	48.53	24866

下载: 导出CSV

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[2]	Wang Y C, Chang J W, Zhu L P, Li X D, Song C J, Fang J F 2018 Adv. Funct. Mater 28 1706317 Google Scholar
[3]	Niu T Q, Lu J, Munir R, Li J B, Barrit D, Zhang X, Hu H L, Yang Z, Amassian A, Zhao K, Liu S Z 2018 Adv. Mater. 30 1706576 Google Scholar
[4]	Li Q Y, Liu H, Hou C H, Yan H M, Li S D, Chen P, Xu H Y, Yu W Y, Zhao Y P, Sui Y P, Zhong Q X, Ji Y Q, Shyue J J, Jia S, Yang B, Tang P Y, Gong Q H, Zhao L C, Zhu R 2024 Nat. EnergyGoogle Scholar
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[6]	Chen S, Wen X M, Huang S J, Huang F Z, Cheng Y B, Green M, Ho-Baillie A 2017 Sol. RRL 1 1600001 Google Scholar
[7]	Brinkmann K, Zhao J, Pourdavoud N, Becker T, Hu T, Olthof S, Meerholz K, Hoffmann L, Gahlmann T, Heiderhoff R, Oszajca M, Luechinger N, Rogalla D, Chen Y, Cheng B, Riedl T 2017 Nat. Commun. 8 13938 Google Scholar
[8]	Liu C, Li W Z, Zhang C L, Ma Y P, Fan J D, Mai Y H 2018 J. Am. Chem. Soc. 140 3825 Google Scholar
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[10]	Wang J, Zhang J, Zhou Y Z, Liu H B, Xue Q F, Li X S, Chueh C C, Yip H L, Zhu Z L, Jen A K Y 2020 Nat. Commun. 11 177 Google Scholar
[11]	Zhang X, Yu Z H, Zhang D, Tai Q D, Zhao X Z 2022 Adv. Energy Mater. 13 2201320
[12]	Zhang H, Xiang W C, Zuo X J, Gu X J, Zhang S, Du Y C, Wang Z T, Liu Y L, Wu H F, Wang P J, Cui Q Y, Su H, Tian Q W, Liu S Z 2022 Angew. Chem. Int. Edit. 62 e202216634
[13]	Chen H N, Yang S H 2017 Adv. Mater. 29 1603994 Google Scholar
[14]	Caliò L, Salado M, Kazim S, Ahmad S 2018 Joule 2 1800 Google Scholar
[15]	Wang K, Liu X Y, Huang R, Wu C C, Yang D, Hu X W, Jiang X F, Duchamp J C, Dorn H, Priya S 2019 ACS Energy Lett. 4 1852 Google Scholar
[16]	Xu B, Zhu Z L, Zhang J B, Liu H B, Chueh C C, Li X S, Jen A K Y 2017 Adv. Energy Mater. 7 1700683 Google Scholar
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[18]	Gong S P, Li H Y, Chen Z Q, Shou C H, Huang M J, Yang S W 2020 ACS Appl. Mater. Interfaces 12 34882 Google Scholar
[19]	Hadadian M, Smatt J H, Correa-Baena J P 2020 Energ. Environ. Sci. 13 1377 Google Scholar
[20]	Wu X, Qi F, Li F Z, Deng X, Li Z, Wu S F, Liu T T, Liu Y Z, Zhang J, Zhu Z L 2020 Energy Environ. Mater. 4 95
[21]	Wang Y, Liu X M, Zhang T Y, Wang X T, Kan M, Shi J L, Zhao Y X 2019 Angew. Chem. Int. Edit. 58 16691 Google Scholar
[22]	Domanski K, Alharbi E A, Hagfeldt A, Gratzel M, Tress W 2018 Nat. Energy 3 61 Google Scholar
[23]	Kye Y H, Yu C J, Jong U G, Chen Y, Walsh A 2018 J. Phys. Chem. Lett 9 2196 Google Scholar
[24]	Wang Z T, Tian Q W, Zhang H, Xie H D, Du Y C, Liu L, Feng X L, Najar A, Ren X D, Liu S Z 2023 Angew. Chem. Int. Edit. 62 e202305815 Google Scholar
[25]	Zhou Q W, Duan J L, Du J, Guo Q Y, Zhang Q Y, Yang X Y, Duan Y Y, Tang Q W 2021 Adv. Sci. 8 2101418 Google Scholar
[26]	Duan J L, Zhao Y Y, He B L, Tang Q W 2018 Angew. Chem. Int. Edit. 57 3787 Google Scholar
[27]	Li M, Yeh H H, Chiang Y H, Jeng U S, Su C J, Shiu H W, Hsu Y J, Kosugi N, Ohigashi T, Chen Y A, Shen P S, Chen P, Guo T F 2018 Adv. Mater. 30 e1801401 Google Scholar
[28]	Liu X Y, Liu Z Y, Sun B, Tan X H, Ye H B, Tu Y X, Shi T L, Tang Z R, Liao G L 2018 Nano Energy 50 201 Google Scholar
[29]	Han Q J, Yang S Z, Wang L, Yu F Y, Zhang C, Wu M X, Ma T L 2021 Sol. Energy 216 351 Google Scholar

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